Enercon Cap Sealing Handbook - Enercon Induction Cap Sealer

Transcription

To watch a brief video on induction sealing basics please
click on the play button above.
To see the rest of the Handbook's tips and techniques
please scroll the document or use the bookmarks provided.
Why Enercon?
Variety
Enercon Has The Largest Range Of Air-Cooled Induction Cap Sealing Systems Available In The Industry
Today, With 8 Models And Multiple Configurations To Suit Your Specific Needs.
Air-cooled Systems
Table Top
Conveyor Mount
Specialty / Capless
Auto Jr.
Super Seal™ (SS50 – SS100)
Pneumatic Jr.
Super Seal™ Jr.
Super Seal™ Deluxe
Rotary / Indexing
Super Seal™ Max
Pressure Belt
Tunnel Sealing Head Design
Enercon’s unique tunnel sealing head design (offered as standard for 53mm closures and smaller)
increases electromagnetic power coupling into the foil, resulting in greater sealing efficiency. This greater
efficiency permits faster line speeds at an equal power level.
Outstanding Service
Enercon stands behind our equipment and customers with 24-hour technical assistance, rapid parts
shipment, as well as loaner and exchange programs. Our worldwide network of representatives provides
local expertise both before and after the sale. For immediate assistance online go to:
www.enerconind.com/support..
Selecting the Right Induction Sealing System
Questions to Answer
With Cap
Capless
1.
2.
3.
4.
5.
6.
Type of Product?
Temperature of Product?
Size of Container?
Container Material?
Diameter of Cap?
Style of Cap: Child-Resistant, Dispensing, Snap
Cap, Standard Flat, Push/Pull, Flip-Top?
7. Liner Material?
8. Conveyor Speed (Feet or Meters per Minute)?
9. Is Wash Down Required?
1.
2.
3.
4.
5.
6.
7.
8.
Type of Product?
Temperature of Product?
Diameter of Container Opening?
Size of Container?
Container Material?
Liner Material?
Inline, Rotary or Indexing Production Line?
Line Speed (Bottles per Minute – Rotary &
Indexing, Feet or Meters per Minute – Pressure
Belt)?
Induction Sealing Rules Of Thumb
Glass containers with dry product can always be sealed. Check with your inner seal supplier when sealing
liquids in glass.
The induction sealing process is still effective when liquid product is on the container lip, with the
exception of some liquids on glass containers.
The operating frequency of the power supply determines the heating pattern of the electromagnetic
field. Higher frequency results in heat concentration on the outside edge of the inner seal, which is
beneficial for the one-piece type liners. As the frequency is lowered, the heating tends to be more
uniform across the inner seal. This is desirable for a wax-bonded type 2-piece inner seal.
Electromagnetic radiation of the type and power level used is not harmful to humans.
1
Enercon Industries Corporation
(262) 255-6070
web: www.enerconind.com
email: [email protected]
Service Options
Startup Made Easy
Enercon offers a discounted Startup service for our customers who are unfamiliar with the installation
and use of induction cap sealing equipment.
As part of the service, an experienced Enercon Field Service Engineer will review your cap sealer
installation, making sure that everything has been done correctly. Or, if you prefer, the Field Service Engineer
can supervise your installation of the cap sealing system.
Once your cap sealing system is up and running, the Field Service Engineer will provide hands-on
training for your operators, as well as training on routine preventive maintenance and troubleshooting for your
maintenance personnel.
Preventive Maintenance
Routine Preventive Maintenance is at the heart of every successful manufacturing operation. Our
experience over the past 30 years has shown that an aggressive preventive maintenance program is the best
insurance against downtime. Solid periodic maintenance will also prolong the life of your equipment. We
have in place a preventive maintenance program, our PMV service, which is designed to give you that
insurance.
At a discounted rate we will supply a Field Service Engineer who will review all of your Enercon
equipment. In addition to ensuring that your Enercon induction cap sealing systems are tuned up and
performing correctly, our Field Service Engineer will provide hands-on training for your operators and
maintenance personnel. He will also identify critical spare parts which should be a part of your maintenance
inventory and help you refine your ongoing maintenance program.
To learn more about our Startup and Preventive Maintenance visits, contact Paul Reed at (262) 2556070, or e-mail him at [email protected]. He is ready to tell you more about these valuable
programs and provide you with a comprehensive pricing package.
Field Service
In conjunction with our Startup and PMV service, Enercon also provides emergency field service that
gets consistently high ratings from our customers in the packaging industry. When a problem cannot be
resolved by your maintenance department we will provide a Field Service Engineer to come to your plant
and repair your equipment.
With extensive hands-on experience and direct access to our Engineering Department, our Field
Service Engineer will ensure that the problem you are experiencing is resolved. He will also determine if
anything else in the system may require repair.
For more information on Field Service visits contact Paul Reed at (262) 255-6070, or e-mail him at
[email protected].
International Service
Check with your local representative for the availability of International Field Service.
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(262) 255-6070
Laboratory Policies And Procedures
In-House Testing
Enercon’s Induction Cap Sealing Laboratory can help you determine the proper sealing head and
power rating, as well as test the suitability of your cap, bottle and liner material for your particular
application. The lab has available every model, power rating and sealing head that Enercon
manufactures, in order to duplicate actual production line conditions accurately.
Equipment research and development, and applications testing, are continuously conducted in the
laboratory. This is an important element in Enercon’s commitment to supply you with technological
leadership in the constantly changing packaging industry.
Induction Cap Sealing Trials
Enercon’s Induction Cap Sealing Laboratory is equipped with a conveyor and tachometer to
reproduce your line speed requirements accurately. The laboratory is also equipped with all of the current
production models of cap sealing equipment, as well as all of the standard and specialty sealing heads
produced by Enercon.
Tests can be performed on all sizes of containers and caps, from a small tube to a 2-gallon jug, with
caps from 5mm to 120mm and larger. As a result of our cooperation with the leading liner material
manufacturers, the laboratory also has a supply of practically all liner materials that are available.
Therefore, we can work with the liner material you have already selected or refer you to the liner material
manufacturers who can help you select the material that is best for your application. The laboratory is also
equipped with a Pack-Vac Leak Detector and a torque meter. The Leak Detector can accommodate all
but the largest containers, for testing the hermetic seal strength, and the torque meter allows the testing of
the application and removal torque.
COST:
There is no charge for the test itself. We do request that you contact our Sales Department
for an RCN (Return Control Number) and send your samples to our facility freight prepaid.
Let us know if you would like your samples returned to you.
RESULTS:
You are welcome to visit our facility and observe the running of your sample. We will
arrange to have your samples available at the time you wish to visit. Typically the visit would
last three to five hours, usually from 9 a.m. until 2 p.m., with a break for lunch. You will be
given a demonstration of the procedures followed for your sample. After a thorough
discussion of your application, you are welcome to take a tour of the facilities and meet
with members of our engineering staff to answer any technical questions you may have.
DATA SHEET:
If you are unable to visit, the results of your sample will be forwarded to you. Any questions
you may have are welcomed by our Sales Engineers.
TIME:
Your sample will be tested in a timely manner, generally within one to two weeks.
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(262) 255-6070
Seal Problem Troubleshooting Tips
Symptom
Partial seal,
weak seal, no
seal.
Probable Cause
Possible Solution
a. Insufficient power from sealer, conveyor too fast
or power set too low.
b. Improper coil height.
c. Insufficient application torque.
d. Induction liner incompatible with the bottle
material.
e. Bottle neck finish has been treated with flame,
corona, or chemically.
f. Imperfections in container finish, land area.
a. See Page 11 for Operating Window Setup
Procedure.
b. See Page 10 for Sealing Head Alignment.
c. See Page 8 for Suggested Application Torque.
d. Contact your supplier, or send samples for
testing.
e. Contact your supplier.
g. Product is touching liner, heat sink effect.
Seal extremely
difficult to
remove (1piece liner).
Cap extremely
difficult to
remove (2piece liner).
a. Power from sealer set too high.
Procedure.
b. Ensure line speed is correct. See Page 11 for
Operating Window Setup Procedure.
b. Conveyor speed is set too slow.
a. Insufficient wax melt, conveyor speed too fast or
output power set too low.
b. Improper coil height (too high).
c. Excessive application torque.
d. Foam liner material welds to polymer in
induction liner.
e. Product touching liner, heat sink effect.
Burnt
Cardboard
Liner.
Low or no
removal torque.
Pinholing.
Pinwheel effect
on liner.
f. See Page 7 to help identify problem, contact
container manufacturer.
g. Check the fill level of product.
a. Excessive power from sealer, conveyor too slow
or power set too high.
b. Bottles back up under sealing head.
c. Insufficient application torque.
d. Gap between liner and container lip caused by
defect in container.
Procedure.
b. See Page 10 for Sealing Head Alignment.
c. See Page 8 for suggested application torque.
d. See Page 11 for Operating Window Setup
Procedure. Material in cap and backing
material on liner may be too compatible –
contact your supplier.
e. Check the fill level of product.
Procedure.
b. See Page 10 for Sealing Head Alignment,
check for cocked cap. Do not stop conveyor
while unit is still running.
c. See Page 8 for suggested application torque or
contact your supplier.
d. Contact your supplier.
a. Insufficient application torque, closure not
securely applied.
b. Excessive application torque, threads of closure
stripped.
c. Void created when wax is absorbed into
pulpboard.
a. See Page 8 for suggested application torque.
a. Excessive power from sealer, conveyor too slow
or power set too high.
b. Product may be attacking liner, if pinholes occur
well after a good seal has been confirmed.
Procedure.
b. Contact your supplier or send samples for
testing.
a. Retorquing too soon after induction sealer.
a. Move
Retorquing
equipment
further
downstream from sealer.
b. See Page 11 for Operating Window Setup
Procedure.
b. Wax was not
completely.
absorbed
into
pulpboard
b. See Page 8 for suggested application torque.
c. Contact your Sales Manager to discuss possible
solutions.
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(262) 255-6070
Liner Types
Before Cap Is Applied To Container
And Induction Sealed
Multilayer Liners
Multilayer liners consist of 4 basic components, as shown.
C
B
A
Pulpboard
Foil
Wax
D
Polymer
B
A
Wax
Pulpboard
After Cap Is Applied To Container
C
Foil
When a multilayer liner passes through the induction field
of the sealing head the following occurs:
D
1. The foil is heated to a temperature that will allow the
polymer to melt and flow.
2. The polymer flows around the land area of the
container filling any voids.
3. The wax is melted and absorbed into the pulpboard,
or similar absorbent material.
4. The polymer cools and hardens creating the hermetic
seal.
Polymer
Before Cap Is Applied To Container
Single-Piece Liners
Single piece liners consist of 2 basic components, as
shown.
A
B
Polymer
Foil
When a single-piece liner passes through the induction
field of the sealing head the following occurs:
After Cap Is Applied To Container
A
Foil
1. The foil is heated to a temperature that will allow the
polymer to melt and flow.
2. The polymer flows around the land area of the
container filling any voids.
3. The polymer cools and hardens creating the hermetic
seal.
B
Polymer
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(262) 255-6070
Cap / Container Issues
Good Container Lip/Liner Contact
Good contact between the liner material and the
container lip is very important. This goes hand in
hand with the amount of torque applied, but can
be a problem even when the torque levels are
good. The land area of the container should be
wide enough and rigid enough to support the
pressures and heating required for a good seal.
Poor Container Lip/Liner Contact
A thin or weak land area can cause poor contact
between the liner material and the container lip.
When the land area is too thin there may not be
enough rigidity in the land area to support the
pressures and heat required for a good seal.
Container Lip Deformations
Gaps between the land area and liner material can
be the result of any number of problems, from mold
imperfections to container material issues.
Regardless of the cause, any gap between the liner
and container land area may cause overheating
and failure of the seal. A gap caused by fall away
of the land area, as well as a gap caused by a
protrusion, is shown. These defects can typically be
detected on the container land area before the
container is capped.
Cocked Cap
A cocked cap is usually due to a problem with the
capping process or a cap or container problem.
The gap created can cause overheating and the
cap itself may actually jam the container under the
sealing head causing the liner to overheat severely.
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(262) 255-6070
Torque Requirements
One of the most common causes of poor or inconsistent sealing is an improperly torqued cap. Whether
the torque is too low or too high, the end result is usually an air gap between the lip of the container and
the liner material. This air gap will usually cause overheating of the liner, but at the very least will create a
gap too large for the polymer to fill. The following table is provided as a general rule of thumb for
determining the torque required for your cap size. For exact torque requirements, contact your cap
manufacturer.
Cap Size
Torque
Cap Size
Torque
15mm
18mm
20mm
22mm
24mm
28mm
33mm
38mm
43mm
48mm
6-9 in./lbs (.68-1nm)
7-10 in./lbs (.79-1.13nm)
8-12 in./lbs (.9-1.35nm)
9-14 in./lbs (1-1.58nm)
10-16 in./lbs (1.13-1.8nm)
12-18 in./lbs (1.35-2.03nm)
15-25 in./lbs (1.69-2.82nm)
17-26 in./lbs (1.92-2.93nm)
18-27 in./lbs (2.03-3.05nm)
19-30 in./lbs (2.14-3.38nm)
53mm
58mm
63mm
70mm
83mm
89mm
100mm
110mm
120mm
21-36 in./lbs (2.37-4.06nm)
23-40 in./lbs (2.59-4.51nm)
25-43 in./lbs (2.82-4.85nm)
28-50 in./lbs (3.16-5.65nm)
40-60 in./lbs (4.51-6.78nm)
45-65 in./lbs (5.08-7.34nm)
50-70 in./lbs (5.65-7.90nm)
52-73 in./lbs (5.87-8.25nm)
55 -75 in./lbs (6.21-8.47nm)
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Liner Issues
Good Seal
A good seal will have good adhesion for the entire
circumference of the bottle opening. Wrinkling will be at a
minimum and on multilayer liners the cap will have no
darkening that would indicate overheating.
No
o discoloration
n indicatess
properr outputt level..
Poor Seal
When the output is too low, line speeds too high, or the
sealing head misaligned the liner material will not adhere
properly to the lip of the bottle. This can range from a seal
that lets go under light pressure to no adhesion to the lip of
the bottle. On multilayer liners there may also be swirling of
the liner due to poor wax absorption into the backing
material.
Overheated Seal
When the output is too high, or line speeds too slow,
overheating of the liner will occur. The liner will often wrinkle
badly, melt into the lip of the bottle, and give off a burned
smell. The burned smell can also contaminate your product.
On multilayer liners the pulpboard will show signs of
discoloration or burning, depending on the severity of the
overheating.
Darkening
g orr burning
g
indicatess outputt levell needss
to
o be
e lowered.
Easy-Peel Liners
Easy-peel liners seal tightly to the lip of the bottle, but allow
for a clean peel from the bottle.
Tamper-Evident Liners
Tamper-evident liners seal tightly to the lip of the bottle, but
leave part of the liner on the lip when opened. This is used to
show evidence that the bottle has indeed been opened.
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Sealing Head Alignment
Tunnel Sealing Head
Flat Sealing Head
Deep Tunnel Sealing Head
The Liner Must Be
Aligned As Shown
1
8"
To 14" Gap
(3 To 6mm)
SIDE VIEW
FRONT VIEW
READY
RUN
REMOTE
AUTO
AUTO
REMOTE
TUNNEL
SEALING HEAD
SETUP
SELECT
SCROLL
DONE
START
STOP
Super Seal ™ Deluxe
FLAT SEALING HEAD
"D"
1
8" GAP
RECOMMENDED
"D"
"D"
CONVEYOR
"D"
CONVEYOR
NOTE: "D" (Distance) Must Be Equal Side To Side And Back To Front Above
Conveyor For Optimum Performance Of Sealing Head.
Sealing Head Alignment Quick Setup
Step 1:
Level and center Sealing Head over conveyor or product.
Step 2:
Fill 2 containers with product to duplicate production weight.
Step 3:
Place one container at each end of the Sealing Head.
Step 4:
Place a proper thickness gauge on top of each cap.
Step 5:
Lower the Sealing Head onto the gauge. The fit should be snug with no change to gap when
the gauge is removed.
Step 6:
Align guide rails to ensure the containers enter and exit the Sealing Head properly centered.
Note: The “1” Sealing Head should be initially set up like the Flat Sealing Head and then skewed to the
proper position for the cap size being sealed. Ensure there are no metal guide rails located beneath
the sealing head.
Setup Information
We recommend that a record be kept of the setup information for each product run with your Cap Sealer.
This information helps ensure consistent and accurate change over between products. This information also
helps troubleshooting of sealing issues if they arise. The Miscellaneous Section in your manual contains a
table for recording this information.
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(262) 255-6070
Operating Window Setup Procedure
As with any piece of equipment it is important to know your Cap Sealer’s operating parameters.
The following is a step-by-step explanation of how to determine the Operating Window for each
package run on a given piece of equipment.
1.
Ensure the unit is installed properly (refer to your Operations Manual) and the sealing head is at the
correct height, centered, and is parallel over the conveyor (refer to Page 10).
2.
Ensure the conveyor speed is set properly for the package being tested.
3.
Ensure the container and caps are free of defects (refer to page 7) and are compatible with each
other. Also check to ensure the torque is correct for the cap size being used (refer to page 8).
4.
Start unit, set the Output % to minimum and run a single container. Check the container for a seal.
5.
If no seal was achieved, increase the Output % in increments of 5-10% until a partial seal is
achieved, increment by 1-2% until a complete seal is achieved (refer to page 9). If a partial seal was
achieved, increase the Output % in increments of 1-2% until a complete seal is achieved (refer to
page 10). This is the minimum set point of the Operating Window.
6.
Once the minimum set point is established, increase the Output % by 1-2% until the liner or cap
show signs of overheating (refer to page 9). Decrease Output by 1% until the overheating is
eliminated. This is the maximum set point of the Operating Window.
7.
Now that the Operating Window is established test the package in the range of Output from
minimum to maximum to determine at what Output % the best seal is achieved. This will be the
production Output level.
8.
Position and run a tightly grouped number of containers that will completely fill the Sealing Head.
Verify the Output % on the meter remains constant and that the seal results are the same on all
containers run.
9.
Record the Minimum/Maximum Output % of the Window, Production Output %, Line Speed, Cap,
Liner and Container information for future reference. Your Operations Manual includes a Production
Information table for this purpose.
10. Repeat all steps for each package run on the equipment.
This information is a useful tool that helps decrease the time required for changeover between
packages, as well as troubleshooting to help determine if you have a package or equipment
problem.
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(262) 255-6070
Super Seal™ Troubleshooting Tips
Symptom
AUTO
O LED Lit and
Output Only 25%
Display Dim Or
Flickers While Unit Is
Running.
Unit Runs But RUN
LED Is Not Lit.
REMOTE LED Lit And
None Of The Buttons
Function.
TEMP LED Is Lit.
FAULT LED Is Lit
AUTO
O LED Lit With No
Control Over
Changing Function.
Display Stops
Flashing, And Shows
A Solid 00 On
Output.
Cause
Solution
1. AUTO Mode Option Not Included With Unit.
2. Unit Waiting For 0-10V Signal From PLC.
1. Output Capacitor Cable Incorrectly Routed.
2. Output Capacitor Body Isolated From Ground.
1. The Output Level Is Below The Adjustable LSI Set Point
(If Unit Has A Stack Light It Will Flash Red).
1. Improperly Installed Control / Display Board.
2.
1.
2.
3.
4.
Failed Control / Display Board.
Ambient Temperature Too High.
Dirty / Failed Cooling Fan.
Failed Temperature Sensor.
1.
2.
3.
4.
Failed Inverter.
Failed Power Connector Board.
Input Voltage Too Low – 208 VAC Or Lower Input
Voltage On A 240 VAC System.
1. Failed Control / Display Board.
2. Improperly Installed Control / Display Board.
1.
2.
3.
4.
Interlocks Not Satisfied.
Defeat Plugs Or Sensors Not Connected.
Failed Inverter.
Open Output.
5. In Remote Mode – Waiting On Remote Start
Command (R
REMOTE
E LED Is Lit).
1. Switch To MAN Mode.
2. Provide 0-10V Signal.
1. Loosen Nut Securing Wire #48, Rotate Wire Away
From Display Board.
2. Snug Capacitor Mounting Hardware The Solder Plugs
On All Capacitor Bodies Read Shorted To Base Plate.
1. Refer To Your Operations Manual To Ensure LSI
Setpoint Level Is Set Properly.
1. Reinstall Control / Display Board Ensuring All Buttons
Depress And Release Properly.
2. Repair / Replace Control / Display Board.
1. Ensure Ambient Temperature 104º F/40º C.
2. Clean / Replace Cooling Fans.
3. Check / Replace Sensor.
1. Perform Inverter Ohm Checks, Replace Inverter.
2. Repair / Replace Power Connector Board.
4. Step Up 208 VAC Using Buck/Boost Or Input
Transformer Or Supply Input Voltage From A 240 VAC
Source.
2. Reinstall Control / Display Board Ensuring All Buttons
Depress And Release Properly.
1. Check Interlocks / Connections.
2. Ensure Defeat Plugs / Sensors Are Installed Properly.
3. Perform Inverter Ohm Checks, Replace Inverter.
4. Check Output Wiring To Output Caps, Ct And Sealing
Head.
5. Change To Manual Mode Or Provide Remote Start.
Super Seal™ Max / Super Seal™ Deluxe Troubleshooting Tips
Symptom
Cause
Solution
Turn Breaker On And / Or Ensure Proper Input Voltage.
Reconnect / Replace Ribbon Cable.
VFD Display Does
Repair / Replace Display Board.
Not Light Up
Repair / Replace Control Board.
Ready Indicator Lit,
Ensure Proper Voltage Is Supplied.
But Dim.
Remove / Isolate Metal.
Ensure Input Power Is Correct And Steady.
Output Fluctuates
Ensure Sealing Head Is Connected Securely.
(More Than 2%).
Replace Inverter.
Inverter Fault.
Check Ambient Temperature.
Clean / Replace Cooling Fan.
Temperature Fault.
Check Wiring / Replace Temp. Sensor.
Repair / Replace Sealing Head.
Replace Output Capacitors (All Caps).
Over Current Fault.
Repair / Replace Output Current Transformer.
Tighten / Replace Wiring.
Interlock Fault
Close Interlock, Install Defeat Connector.
System Error
Refer To Operations Manual For System Error
Message
Description.
1. Ribbon Cable.
1. Reconnect / Replace Ribbon Cable.
Communication
2. Display Board.
2. Repair / Replace Display Board.
Error Message
3. Control Board.
3. Repair / Replace Control Board.
NOTE: For symptoms not listed on table contact Enercon Industries Customer Service (262) 255-6070.
1. Circuit Breaker / Input Voltage.
2. Ribbon Cable.
3. Failed Display Board.
4. Failed Control Board.
1. Low Input Voltage.
2. Control Board.
1. Sealing Head Coupling Into Nearby Metal.
2. Inadequate Input Power.
3. Sealing Head Connections.
1. Inverter
2. Control Board.
1. Over Temperature.
2. Cooling Fan.
3. Temperature Sensor.
4. Control Board.
1. Sealing Head.
2. Output Capacitors.
3. Output Current Transformer.
4. Loose Wiring.
1. Open Interlock.
1. System Has Experienced An Internal Error.
1.
2.
3.
4.
1.
2.
1.
2.
3.
4.
1.
2.
1.
2.
3.
4.
1.
2.
3.
4.
1.
1.
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Compak™ / Compak™ Convertible / Integral II / Early Super Seal™
Troubleshooting Tips
Symptom
Front
Panel LEDs
FAULT
STANDBY
FAULT
Meter
00
Bd
LED
N/A
Seal
Cause
1.
2.
3.
4.
No Seal
Water Hoses Reversed.
Low Water Pressure.
Pressure Switch.
Failed Control Board.
1. Failed Inverter / Chopper.
GEN
STANDBY
GEN
TEMP
STANDBY
TEMP
Power Supply
Will Not Start
None
00
Lit
00
N/A
00
N/A
2.
3.
4.
5.
No Seal
No Seal
No Seal
Failed Output Capacitor.
Failed Sealing Head.
Failed Output Leads.
Solution
1.
2.
3.
4.
Swap Hoses.
Check Water Level And Strainer.
Check Wiring / Replace Switch.
1. Replace Device And Gate
Leads.
3. Replace All Capacitors.
4. Replace Sealing Head.
5. Replace Output Leads
1. Insufficient Cooling Water Or Air
Flow.
2. Failed Temp Switch.
1. Check Water System And
Cooling Fan.
2. Replace Temp Switch.
3. Repair/Replace Control Board.
1. Input Power Missing.
2. Ribbon Cable.
4. Miswiring In Power Supply.
1. Check Voltage Source.
2. Connect / Replace Ribbon
Cable.
3. Replace Circuit Breaker.
5. Repair / Replace Membrane
Switch.
1. Check Interlocks / Connections.
2. Repair / Replace Membrane
Switch.
4. Correct Wiring.
3. Failed Circuit Breaker.
5. Failed Membrane Switch.
1. Interlocks Not Satisfied.
2. Failed Membrane Switch.
Power Supply
Will Not Start
STANDBY
Power Supply
Will Not Start
STANDBY
02 to 06
Lit
No Seal
1. Failed Inverter / Chopper.
1. Replace Failed Device.
Power Supply
Will Not Start
STANDBY
07 to 12
Lit
No Seal
1. Defective Output Capacitor.
1. Replace All Output Capacitors.
00
N/A
No Seal
1. Remove / Isolate Metal.
STANDBY
RUN
1. Sealing Head Coupling Into
Nearby Metal.
Lit If
May Not Be
2. Inadequate Input Power.
25% to <100 Limit Is
Affected
3. Failed Output Leads.
Met
Meter
Fluctuates
STANDBY
RUN
1.
25% - 100%
2.
But Fluctuates Not Lit Intermittent
3.
Under Load.
4.
1.
2.
3.
4.
Meter
Fluctuates
STANDBY
RUN
25% - 100%
Fluctuates At
Set Point.
Unable To
Achieve Full
Output
Not Lit Not Affected
Overloading System.
Inadequate Input Power.
Failed Output Leads.
2. Correct Input Power.
3. Replace Output Leads.
Increase Spacing Of Bottles.
Correct Input Power.
Replace Output Leads.
1. Failed Membrane.
1. Replace Membrane.
1. Sealing Head Alignment.
Intermittent
Seals
STANDBY
RUN
25% - 100%
Not Lit Intermittent 2. Liner / Container Compatibility
Problem.
3. Torque Problem.
1. See Page 16 For Sealing Head
Alignment.
2. Verify Liner / Container
Compatibility.
3. See Page 9 For Torque Listings.
Unit Drops Out
Intermittently
STANDBY
RUN
(intermittent)
25% - 100%
&
00%
1. Stall / Backup Sensor.
Not Lit Intermittent 2. Interlocks.
3. Failing Output Leads.
1. Reset / Replace Sensor.
2. Check Interlocks.
3. Replace Output Leads.
NOTE: For symptoms not listed on table contact Enercon Industries Customer Service (262) 255-6070.
13
(262) 255-6070
Compak™ Jr. / Auto Jr. / Super Seal™ Jr. Troubleshooting Tips
Symptom
Cause
Resolution
Front Panel Is Blank With
Power Applied
1.
2.
3.
4.
5.
6.
7.
8.
Sealing Head Connection (SSJr Only).
Power Cord Condition.
Voltage Missing at Outlet.
Fuse Open.
Ribbon Cable Condition.
Control Board.
Power Board.
Internal Wiring.
1.
2.
3.
4.
5.
6.
7.
8.
Fully Seat Sealing Head Connector.
Replace / Reconnect Power Cord.
Correct Issue At Outlet.
Replace Fuse.
Repair / Replace Power Board.
Correct Replace Wiring.
Front Panel is Lit But Unit
Doesn’t Cycle Or Run
1.
2.
3.
4.
5.
6.
7.
Sealing Head / Unit Connection (CJr Only).
Connector Pins Damaged (CJr & SSJr).
Trigger Switch (CJr & SSJr).
Proximity Sensor (AJr Only).
Remote Start Contact (SSJr Only).
Ribbon Cable Condition.
Control Board.
1.
2.
3.
4.
5.
6.
7.
Securely Set Locking Ring.
Repair / Replace Pins / Connectors.
Repair / Replace Switch.
Properly Adjust / Align or Replace Sensor.
Repair / Replace N.O. Momentary Contact.
Timer Cycles When
Power Is Turned On
1.
2.
3.
4.
Trigger Switch (CJr & SSJr).
Proximity Sensor (AJr Only).
Remote Start Contact (SSJr Only).
Control board.
1.
2.
3.
4.
Repair / Replace Switch.
Properly Align, Adjust, Or Replace Sensor.
Repair / Replace N.O. Momentary Contact.
Timer Counts Down
Properly, But Sealing On
LED Is Not Lit
1.
2.
3.
4.
5.
6.
7.
8.
Sealing Head Connection (AJr Only).
Connector Pins Damaged (CJr Only).
Inverter Device (CJr & AJr Only).
MOSFETS (SSJr Only).
LED
Control Board.
Power Board.
1.
2.
3.
4.
5.
6.
7.
8.
Ensure Coil Connection Is Good.
Replace Failed Inverter.
Replace Failed MOSFET.
Replace LED.
Repair / Replace Power Board.
Unit Runs And Seals But
FOIL PRESENT LED is
Never Lit (CJr & AJr)
1.
2.
3.
4.
5.
Foil Present LED Circuit Not Set Properly.
Connector Pins Damaged (CJr Only).
LED
Control Board.
1.
2.
3.
4.
5.
*Adjust Foil Present Circuit.
Replace LED.
Unit Runs And Seals But
MISSING FOIL is Always
Lit (SSJr Only)
1. MISSING FOIL Circuit Not Set Properly.
2. Control Board.
1. Adjust MISSING FOIL Circuit.
Unit Runs Properly and
Both LED’s Function, But
No Seal is Achieved
1. Missing Liner Material In Cap.
2. Sealing Head / Cap Alignment.
3. Container And Liner Compatibility.
1. Only Use Caps With An Appropriate Liner.
2. Ensure Proper Centering And Gap.
3. Contact Your Supplier.
1. Proximity Sensor.
1. Properly Align, Adjust, Or Replace Sensor.
1. Causes For Each Code Vary.
1. Contact Enercon Industries Customer Service.
Input Power Must Be
Cycled Off And On
Repeatedly To Seal
(AJr Only)
F01 – F07 Error Message
Is Displayed (SSJr Only)
*Some Compak™ Jr’s Will Be Adjusted w/Pot Inside Unit, While Other Units Cannot Be Adjusted. These Can Be Identified By The Lack
Of Foil Indicator Adjustment Hole In The Front Panel. (CJr = Compak™ Jr. / AJr = Auto Jr. / SSJr =Super Seal™ Jr.)
14
(262) 255-6070
Inverter / Chopper Ohm Checks
D
B
E
F
A
C
G
Chopper Will Have D & E Shorted Together.
Meter Hook-Up
VOM (Rx1)
DVOM (Diode)
(+) A to (-) B
(-) A to (+) B
(+) A to (-) C
(-) A to (+) C
(+) B to (-) C
(-) B to (+) C
(+) D to (-) E w/Gates Disconnected
(+) G to (-) F w/Gates Disconnected
Open
§ 20
§ 20
Open
§ 40
Open
Slight Deflection, Then Open
Slight Deflection, Then Open
Open
.4 V
.4 V
Open
.8 V
Open
Open
Open
• Any “Zero” ohm reading constitutes a bad Semiconductor.
• Apply an extremely thin film of thermal compound.
• Securely mount devices, torque mounting bolts to 30 inch-pounds or 3.39 N-m.
• Gate leads MUST be replaced with devices.
Maintenance List
Daily Checks
Water Level*
Options Function
Coil Alignment
Output Range
Monthly Checks
Check Strainer*
Test Interlocks
Blow Out Unit**
Check / Clean Fans**
Clean Radiator*
Inventory Spare Parts
Check Output Cables / Sealing Head*
*Applies to Water Cooled Equipment Only.
**Use LP Air
Quarterly Checks
March
h
Flush Unit*
June
e
Vinegar Flush Unit *
Check Connections
Septemberr
Flush Unit*
Decemberr
Vinegar Flush Unit *
Check Connections
Oil Fan Motor
Date Performed
Performed by
15
(262) 255-6070
Oil Filled Output Capacitor Replacement
Some Enercon Cap Sealers use oil filled output capacitors that are mounted in banks of 2 to 4 capacitors,
some with single banks others with multiple banks. Regardless of the configuration of your Cap Sealer there
are several guidelines to adhere to when replacing capacitors on your system. Use the following guidelines to
ensure your replacement capacitors are installed properly.
1. Whenever an output capacitor fails in a bank it is recommended that all the capacitors in that bank be
replaced at the same time. Since the failure of one capacitor can stress the remaining capacitors in that
bank another failure may occur in a relatively short period of time.
2. Once the old capacitors are removed ensure the mounting surface is clean and any Nomex insulating
material is in good shape (not all Cap Sealers have a Nomex insulator). Clean the mounting surface and
replace any damaged insulators as required.
3. The Super Seal™ 50, 75 & 100 Cap Sealers have gasket material that is used for spacing of the mounting
plate(s). This allows air flow across the body of the capacitors as well as allowing expansion when heating
occurs. When installing the mounting plate(s) to the capacitor bank, only tighten the holding screws or
acorn nuts until the gasket material just begins to compress. DO NOT OVER
R TIGHTEN as damage may
occur to the capacitors.
4. The Compak™ Cap Sealers use a strip of gasket material to keep the capacitors from sagging at the
studs. This also allows air flow around the capacitors as well as expansion when heating occurs. If the
gasket material is damaged, or sticks to the old capacitors when they are removed, install new gasket
material onto the base plate beneath the capacitor bank.
5. The Super Seal™ Max, Super Seal™ Deluxe, Compak™ Convertible and Integral II Cap Sealer models use
brackets for mounting the output capacitors. The Super Seal™ Max and Super Seal™ Deluxe also have a
circuit board mounted to the studs for monitoring the output. These brackets and boards provide the
proper spacing of the capacitors and should be reinstalled in the same configuration, replacing only the
capacitors. DO NOTT OVER
R TIGHTEN brackets to the capacitor body as damage may occur to the
capacitors.
6. Reinstall all wires and bus bars onto the same points on the capacitors, or boards, that they were removed
from, this ensures the Cap Sealer’s operating frequency will remain the same. Refer to your system’s
operations manual for the configuration of your particular output capacitor bank.
7. Reinstall the washers, lock washers and ¼ - 20 nuts onto the capacitor studs and torque the nuts to 20 in..
lbss (2.26
6 Nm), DO NOT OVER
R TORQUE the nuts as this may damage the internal connections to the studs of
the capacitor.
Capacitor Stud Board/Bus Bar Output Cable Washers & Nut
16
(262) 255-6070
Water System Flush
Note: These Procedures are only applicable to water-cooled systems.
A system flush is one of the most important steps you can take in maintaining your equipment. We recommend
flushing your system quarterly, alternating between fresh water and vinegar flushes. The fresh water flush is easily
accomplished by simply removing the old water from your induction sealer and replacing it with fresh distilled
water. The vinegar flush may require scheduling during a period of down time and will require the following
materials.
♦
♦
♦
♦
♦
♦
♦
♦
One to five gallons of white vinegar
One to five gallons of distilled water (water savers only)
Wet/dry vacuum to remove water (water savers only)
Acid pump (city water)
Five gallon plastic pail (city water only)
Low-pressure air supply
Goggles or safety glasses
Rubber gloves
Once the required materials are together use the following steps to perform the vinegar flush.
1. Remove all power from the system, following all safety procedures.
2. Remove all covers to gain access to the water tank.
3. Drain water using the wet/dry vacuum, acid pump or other equipment. Remove output hose and blow LP
Air through the unit, reattach hose. City water systems: blow air through the unit.
4. Fill the water tank with vinegar. City water systems: connect acid pump to the inlet side of the water path,
run outlet hose to pail and fill pail with vinegar.
5. Restore power to water saver.
6. Turn on water saver and let run until vinegar is distributed through system. City water systems: operate acid
pump until vinegar is returned to the pail.
7. Let stand for 20 to 30 minutes.
8. Repeat Steps 6 and 7 for two to three hours.
9. Repeat Steps 1 through 3 to remove vinegar.
10. Repeat Steps 4 through 6 using fresh water to flush vinegar. City water systems: reattach unit to city water.
11. Repeat Steps 1 through 3 on water savers to remove fresh water. Fill water tank with distilled water and
replace all covers making sure that the system is in a safe operating condition. If water may freeze, use a
60/40 mixture of ethylene glycol. DO NOT USE ANTIFREEZE.
Pump Pressure Adjustment
Replacement Procon pumps for our standard water saver systems are shipped set at the manufacturer’s
pressure setting, typically 60 psi. When a replacement pump is installed in your water saver system it may require
the pressure be adjusted to match the pressure setting of your original pump. The following is a detailed
explanation of how the pressure is set on these pumps. Refer to page 30 for pump parts breakdown.
1.
2.
3.
On the pump you will find 2 acorn nuts. The large nut covers the strainer and the small nut covers the
Pressure Set Screw. Remove the small acorn nut using a ¾ ″ open end wrench or socket.
The Pressure Set Screw is slotted to allow setting the pressure using a standard screwdriver. Turn the set
screw clockwise to raise the pressure and counterclockwise to lower the pressure. In most cases you will
need to lower the pressure on replacement pumps. Final pressure should be 10 – 15 psi on older systems
and 30 – 35 psi on newer systems.
Reinstall the small acorn nut onto the Pressure Set Screw, ensure that the pressure does not increase as you
tighten the acorn nut, and tighten using a ¾ ″ open end wrench or socket.
Your pressure should now be set and your system ready to be placed back into production. If you have any
problems or further questions on this procedure please contact Enercon Industries Customer Service Department
(262) 255-6070.
17
(262) 255-6070

Enercon Cap Sealing Handbook - Enercon Induction Cap Sealer

Transcription

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Windblatt 03/2011 ENERCON Quality Assurance